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ignore_handler_s set_constraint_handler_s static_assert File input/output clearerr(清除/复位) fclose feof ferror fflush(清空文件缓冲区) fgetc fgetpos fgets fgetwc fgetws File input/output fopen fopen_s fprintf fprintf_s fputc fputs fputwc fputws fread freopen freopen_s fscanf fscanf_s fseek fsetpos ftell fwide fwprintf fwprintf_s fwrite fwscanf fwscanf_s getc getchar gets gets_s getwchar perror printf printf_s putc putchar puts putwc putwchar remove rename rewind scanf scanf_s setbuf setvbuf snprintf sprintf sscanf sscanf_s swprintf swprintf_s swscanf swscanf_s tmpfile tmpfile_s tmpnam tmpnam_s ungetc ungetwc vfprintf vfprintf_s vfscanf vfscanf_s vfwprintf vfwprintf_s vfwscanf vfwscanf_s vprintf vprintf_s vscanf vscanf_s vsnprintf vsprintf vsscanf vsscanf_s vswprintf vswprintf_s vswscanf vswscanf_s vwprintf vwprintf_s vwscanf vwscanf_s wprintf wprintf_s wscanf wscanf_s Localization support lconv LC_ALL LC_COLLATE LC_CTYPE LC_MONETARY LC_NUMERIC LC_TIME localeconv Localization support setlocale Numerics abs acos acosf acosh acoshf acoshl acosl asin asinf asinh asinhf asinhl asinl atan atan2 atan2f atan2l atanf atanh atanhf atanhl atanl cabs cabsf cabsl cacos cacosf cacosh cacoshf cacoshl cacosl carg cargf cargl casin casinf casinh casinhf casinhl casinl catan catanf catanh catanhf catanhl catanl cbrt cbrtf cbrtl ccos ccosf ccosh ccoshf ccoshl ccosl ceil ceilf ceill cexp cexpf cexpl cimag cimagf cimagl clog clogf clogl CMPLX CMPLXF CMPLXL Common mathematical functions complex Complex number arithmetic conj conjf conjl copysign copysignf copysignl cos cosf cosh coshf coshl cosl cpow cpowf cpowl cproj cprojf cprojl creal crealf creall csin csinf csinh csinhf csinhl csinl csqrt csqrtf csqrtl ctan ctanf ctanh ctanhf ctanhl ctanl div double_t erf erfc erfcf erfcl erff erfl exp exp2 exp2f exp2l expf expl expm1 expm1f expm1l fabs fabsf fabsl fdim feclearexcept fegetenv fegetexceptflag fegetround feholdexcept feraiseexcept fesetenv fesetexceptflag fesetround fetestexcept feupdateenv FE_ALL_EXCEPT FE_DFL_ENV FE_DIVBYZERO FE_DOWNWARD FE_INEXACT FE_INVALID FE_OVERFLOW FE_TONEAREST FE_TOWARDZERO FE_UNDERFLOW FE_UPWARD Floating-point environment float_t floor floorf floorl fma fmaf fmal fmax fmaxf fmaxl fmin fminf fminl fmod fmodf fmodl fpclassify FP_INFINITE FP_NAN FP_NORMAL FP_SUBNORMAL FP_ZERO frexp frexpf frexpl HUGE_VAL HUGE_VALF HUGE_VALL hypot hypotf hypotl I ilogb ilogbf ilogbl imaginary imaxabs imaxdiv INFINITY isfinite isgreater isgreaterequal isinf isless islessequal islessgreater isnan isnormal isunordered labs ldexp ldexpf ldexpl ldiv lgamma lgammaf lgammal llabs lldiv llrint llrintf llrintl llround llroundf llroundl log log10 log10f log10l log1p log1pf log1pl log2 log2f log2l logb logbf logbl logf logl lrint lrintf lrintl lround lroundf lroundl MATH_ERREXCEPT math_errhandling MATH_ERRNO modf modff modfl nan NAN nanf nanl nearbyint nearbyintf nearbyintl nextafter nextafterf nextafterl nexttoward nexttowardf nexttowardl Numerics pow powf powl Pseudo-random number generation rand RAND_MAX remainder remainderf remainderl remquo remquof remquol rint rintf rintl round roundf roundl scalbln scalblnf scalblnl scalbn scalbnf scalbnl signbit sin sinf sinh sinhf sinhl sinl sqrt sqrtf sqrtl srand tan tanf tanh tanhf tanhl tanl tgamma tgammaf tgammal trunc truncf truncl Type-generic math _Complex_I _Imaginary_I Program support abort atexit at_quick_exit exit EXIT_FAILURE EXIT_SUCCESS getenv getenv_s jmp_buf longjmp Program support utilities quick_exit raise setjmp SIGABRT SIGFPE SIGILL SIGINT signal SIGSEGV SIGTERM sig_atomic_t SIG_DFL SIG_ERR SIG_IGN system _Exit Strings atof atoi atol atoll btowc c16rtomb c32rtomb char16_t char32_t isalnum isalpha isblank iscntrl isdigit isgraph islower isprint ispunct isspace isupper iswalnum iswalpha iswblank iswcntrl iswctype iswdigit iswgraph iswlower iswprint iswpunct iswspace iswupper iswxdigit isxdigit mblen mbrlen mbrtoc16 mbrtoc32 mbrtowc mbsinit mbsrtowcs mbsrtowcs_s mbstate_t mbstowcs mbstowcs_s mbtowc memchr memcmp memcpy memcpy_s memmove memmove_s memset memset_s Null-terminated byte strings Null-terminated multibyte strings Null-terminated wide strings strcat strcat_s strchr strcmp strcoll strcpy strcpy_s strcspn strerror strerrorlen_s strerror_s Strings library strlen strncat Thread support call_once cnd_broadcast cnd_destroy cnd_init cnd_signal cnd_timedwait cnd_wait mtx_destroy mtx_init mtx_lock mtx_plain mtx_recursive mtx_timed mtx_timedlock mtx_trylock mtx_unlock once_flag ONCE_FLAG_INIT thrd_busy thrd_create thrd_current thrd_detach thrd_equal thrd_error thrd_exit thrd_join thrd_nomem thrd_sleep thrd_success thrd_timedout thrd_yield Thread support library thread_local tss_create tss_delete TSS_DTOR_ITERATIONS tss_get tss_set Type support Boolean type support library Fixed width integer types FLT_EVAL_METHOD FLT_ROUNDS max_align_t NULL Numeric limits offsetof ptrdiff_t size_t Type support Variadic functions Variadic functions va_arg va_copy va_end va_list va_start
文字

在初始化struct或union类型的对象时,初始值设定项必须是成员的非空的,括号括起来的以逗号分隔的初始值设定项列表:

= {表达式,...}


(直到C99)

= {指定者(可选)表达式,...}


(自C99以来)

其中指示符是.表单[索引中的表单成员和数组指示符的各个成员标识符的序列(空格分隔或相邻)]

所有未明确初始化的成员都会以与具有静态存储持续时间的对象相同的方式隐式初始化。

说明

初始化联合时,初始化程序列表必须只有一个成员,它将初始化联合的第一个成员,除非使用了指定的初始化程序(自C99以来)。

union { int x; char c[4]; }
  u = {1},           // makes u.x active with value 1
 u2 = { .c={'\1'} }; // makes u2.c active with value {'\1','\0','\0','\0'}

当初始化一个结构时,列表中的第一个初始化器初始化第一个声明的成员(除非指定了指定符)(自C99开始),并且没有指定符的所有后续初始化器(自C99开始)初始化在先前由表达。

struct point {double x,y,z;} p = {1.2, 1.3}; // p.x=1.2, p.y=1.3, p.z=0.0div_t answer = {.quot = 2, .rem = -1 };      // order of elements in div_t may vary

指示符使下列初始化程序初始化由指定符描述的结构成员。然后按照声明的顺序继续初始化,从在指定符描述的声明之后声明的下一个元素开始。struct {int sec,min,hour,day,mon,year;} z = {.day = 31,12,2014,.sec = 30,15,17}; //将z初始化为{30,15,17,31,12,2014}

(自C99以来)

提供比成员更多的初始化器是错误的。

嵌套初始化

如果结构体或联合体的成员是数组,结构体或联合体,则大括号括起来的初始化程序中相应的初始化程序是对这些成员有效的任何初始化程序,除了它们的大括号可以省略如下:

如果嵌套的初始化程序以一个左大括号开始,则整个嵌套初始化程序直到其大括号初始化相应的成员对象。每个左开口大括号建立一个新的当前对象。当前对象的成员以自然顺序进行初始化,除非使用了指示符(自C99起):数组元素以下标顺序,声明顺序的struct成员,仅为任何联合的第一个声明成员。当前对象内的子对象没有被右括号显式初始化,它们被隐式初始化。

struct example {
    struct addr_t {
       uint32_t port;    } addr;
    union {
       uint8_t a8[4];
       uint16_t a16[2];    } in_u;};struct example ex = { // start of initializer list for struct example                     { // start of initializer list for ex.addr                        80 // initialized struct's only member                     }, // end of initializer list for ex.addr                     { // start of initializer-list for ex.in_u                        {127,0,0,1} // initializes first element of the union                     } };

如果嵌套的初始化程序不是以大括号开始,则只有足够的初始化程序才会考虑成员数组的元素或成员struct或union; 任何剩余的初始化器都将被初始化为下一个结构成员:

struct example ex = {80, 127, 0, 0, 1}; // 80 initializes ex.addr.port                                        // 127 initializes ex.in_u.a8[0]                                        // 0 initializes ex.in_u.a8[1]                                        // 0 initializes ex.in_u.a8[2]                                        // 1 initializes ex.in_u.a8[3]

When designators are nested, the designators for the members follow the designators for the enclosing structs/unions/arrays. Within any nested bracketed initializer list, the outermost designator refers to the current object and selects the subobject to be initialized within the current object only. struct example ex2 = { // current object is ex2, designators are for members of example                        .in_u.a80=127, 0, 0, 1, .addr=80};  struct example ex3 = {80, .in_u={ // changes current object to the union ex.in_u                            127,                            .a82=1 // this designator refers to the member of in_u                       } }; If any subobject is explicitly initialized twice (which may happen when designators are used), the initializer that appears later in the list is the one used (the earlier initializer may not be evaluated): struct {int n;} s = {printf("a\n"), // this may be printed or skipped                      .n=printf("b\n")}; // always printed Although any non-initialized subobjects are initialized implicitly, implicit initialization of a subobject never overrides explicit initialization of the same subobject if it appeared earlier in the initializer list: #include <stdio.h> typedef struct { int k; int l; int a2; } T; typedef struct { int i;  T t; } S; T x = {.l = 43, .k = 42, .a1 = 19, .a0 = 18 };  // x initialized to {42, 43, {18, 19} } int main(void) {     S l = { 1,          // initializes l.i to 1            .t = x,      // initializes l.t to {42, 43, {18, 19} }            .t.l = 41,   // changes l.t to {42, 41, {18, 19} }            .t.a1 = 17 // changes l.t to {42, 41, {18, 17} }           };     printf("l.t.k is %d\n", l.t.k); // .t = x sets l.t.k to 42 explicitly                                     // .t.l = 42 would zero out l.t.k implicitly } Output: l.t.k is 42  However, when an initializer begins with a left open brace, its current object is fully re-initialized and any prior explicit initializers for any of its subobjects are ignored: struct fred { char s4; int n; }; struct fred x  = { { { "abc" }, 1 }, // inits x0 to { {'a','b','c','\0'}, 1 }                       0.s0 = 'q'   // changes x0 to { {'q','b','c','\0'}, 1 }                    }; struct fred y  = { { { "abc" }, 1 }, // inits y0 to { {'a','b','c','\0'}, 1 }                      0 = { // current object is now the entire y0 object                              .s0 = 'q'                              } // replaces y0 with { {'q','\0','\0','\0'}, 0 }                     };

(自C99以来)

注释

任何初始化器中子表达式的评估顺序都是非确定的:

int n = 1;struct {int x,y;} p = {n++, n++}; // unspecified, but well-defined behavior:                                  // n is incremented twice in arbitrary order                                  // p equal {1,2} and {2,1} are both valid

在C中,初始化器的支撑列表不能为空(请注意,C ++允许空列表,并且还要注意C中的结构不能为空):

struct {int n;} s = {0}; // OKstruct {int n;} s = {}; // Error: initializer-list cannot be emptystruct {} s = {}; // Error: struct cannot be empty, initializer-list cannot be empty

与所有其他初始化一样,初始化器列表中的每个表达式在初始化静态或线程本地存储持续时间数组时都必须是常量表达式:

static struct {char* p} s = {malloc(1)}; // error

初始化程序列表可能会有一个尾随逗号,这会被忽略。

struct {double x,y;} p = {1.0,                          2.0, // trailing comma OK                          };

#include <stdio.h>#include <time.h>
 int main(void){
    char buff[70];    // designated initalizers simplify the use of structs whose    // order of members is unspecified
    struct tm my_time = { .tm_year=112, .tm_mon=9, .tm_mday=9,                          .tm_hour=8, .tm_min=10, .tm_sec=20 };    strftime(buff, sizeof buff, "%A %c", &my_time);    puts(buff);}

可能的输出:

Sunday Sun Oct  9 08:10:20 2012

参考

  • C11标准(ISO / IEC 9899:2011):

    • 6.7.9 / 12-38初始化(p:140-144)

  • C99标准(ISO / IEC 9899:1999):

    • 6.7.8 / 12-38初始化(p:126-130)

  • C89 / C90标准(ISO / IEC 9899:1990):

    • 3.5.7 / 9-初始化

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